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Antibacterial agents

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Touheed Ovi

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Antibacterial agents Antibiotics: Antibiotics are chemical substances produced by various species of microorganisms such as bacteria, fungi, actinomycetes etc and are used for either killing or inhibiting the growth of other pathogenic microorganisms without affecting the host tissue.
Properties of an ideal antibiotic:  It should have a broad spectrum of antimicrobial activity.  It should exert its action in low concentration  It should have bactericidal activity rather than bacteriostatic activity  It should exhibit selective and effective antimicrobial activity.  It should be highly toxic for the parasite but completely atoxic for the host.  No bacterial resistance should be developed rapidly.  It should not interfere with the host’s natural defense mechanism such as phagocytosis and production of antibodies.
 It should have sufficient solubility in aqueous fluid to facilitate good distribution to all body tissues.  It should be excreted in urine in bactericidal concentration specially in urinary tract infection.  It’s antimicrobial efficacy should not be reduced by body fluids, exudates, plasma protein or tissue enzymes.  Antibiotic should possess sufficient chemical stability that it can be isolated, processed that stored for reasonable length of time without deterioration of potency.  The rates of biotransformation and elimination of the antibiotic should be sufficiently slow to allow a convenient dosing schedule. Properties of an ideal antibiotic: cont…
Tetracycline Example: Oxytetracycline, Demeclocycline, Methacycline. M/A: Tetracyclines inhibit bacterial protein synthesis by binding to the 30S bacterial ribosome and preventing access of aminoacyl tRNA to the acceptor (A) site on the mRNA-ribosome complex. These drugs enter gram-negative bacteria by passive diffusion through the hydrophilic channels formed by the porin proteins of the outer cell membrane and by active transport via an energy-dependent system that pumps all tetracyclines across the cytoplasmic membrane. Entry of these drugs into gram-positive bacteria requires metabolic energy, but is not as well understood.
Mechanism of antibacterial action There are five main mechanisms by which antibacterial agent act- Inhibition of cell metabolism: Antibacterial agents which inhibit cell metabolism are called antimetabolites. These compounds inhibit the metabolism of microorganism but not the metabolism of the host. They can do this by inhibiting an enzyme catalyzed reaction which is present in the bacterial cell, but not in animal cells. e. g. sulfonamides. Inhibition of bacterial cell wall synthesis: Inhibition of bacterial cell wall synthesis leads to bacterial cell lysis and death.
Interaction with plasma membrane: Some antibacterial agents interact with the plasma membrane of bacterial cells to affect the membrane permeability. This has fatal results for the cell. E. g. polymixins, tyrothricin. Disruption of protein synthesis: Disruption of protein synthesis means that essential proteins and enzymes required for the cell’s survival can no longer be made. E. g. rifamycins, aminoglycosides, tetracyclins and chloramphenicol Inhibition of nucleic acid transcription and replication Inhibition of nucleic acid function prevents cell division and/or the synthesis of essential proteins. e. g. –nalidixic acid, proflavin, fluoroquinolone
Classification of Antibiotics: Although there are several classification schemes for antibiotics, based on bacterial spectrum (broad versus narrow) or type of activity (bactericidal vs. bacteriostatic), the most useful is based on chemical structure. Antibiotics within a structural class will generally have similar patterns of effectiveness, toxicity, and allergic potential. The main classes of antibiotics are:  Beta-Lactams  Penicillins  Cephalosporins  Macrolides  Fluoroquinolones  Tetracyclines  Aminoglycosides
β-Lactam Characteristics  Same Mechanism of Action : Inhibit cell wall synthesis  Bactericidal (except against Enterococcus sp.); time-dependent killers  Short elimination half-life  Primarily renal elimination  Cross-allergenicity -except aztreonam
Mechanism of Action (ALL β-lactams)  Interfere with cell wall synthesis by binding to penicillin-binding proteins (PBPs) which are located in bacterial cell walls  Inhibition of PBPs leads to inhibition of peptidoglycan synthesis→ Cell death
Mechanisms of Resistance 1. production of β-lactamase enzymes  most important and most common  hydrolyzes beta-lactamring causing inactivation 2. Trapping mechanism  Some β –lactams tightly bind with β – lactamase and stay outside the bacterial cell. Thus, these beta- lactams can’t enter the bacterial cell wall to combine with the PBPs. 3. Modification of target PBPs.  responsible for methicillin resistance in staphylococci and penicillin resistance in pneumococci.
Mechanisms of Resistance 4. Impaired penetration of drug to target PBPs.  which occurs only in G-species, is due to impermeability of the outer membrane that is present in G- but not in G+ bacteria. 5. The shortage of autolytic enzyme.  Under this circumstance, the beta-lactams have normal inhibiting action, but their kill effects are very poor. 6. The presence of an efflux pump.  Some organisms also may transport beta- lactam antibiotics from the periplasm back across the cell wall via an efflux pump
Penicillins  The structure of the penicillins consists of a thiazolidine ring connected to a beta-lactamring, which is attached to a side chain.  All penicillins are derived from 6-Amino- penicillanic acid.  The various penicillins differ in their side chain structure.
Classification of penicillin  Penicillins are divided into natural and semisynthetic ones  Natural penicillins: extracted from the cultural solution of penicillia.  penicillin G  Is pH sensitive. Therefore not given orally.  Effective against Gram-positive cells  Susceptible to penicillinase  Semisynthetic penicillins:  Produce by growing Penicillium in culture so that only the nucleus is synthesized. Attach R group in lab.  Or, grow Penicillium, extract natural penicillin, remove R group, and attach wanted R group.  Have broader spectrum. Are effective against Gram-negative cells, too.  Are not resistant to penicillinases
Semisynthetic penicillins:  Acid-stable penicillins(e.g. penicillin V);  Penicillinase-resistant penicillins (e.g. oxacillin);  Extended-spectrum penicillins (e.g. ampicillinand antipseudomonal);  Antistaphylococcal penicillins (e.g. nafcillin).
Mechanisms of Resistance - Penicillins  Inactivation of antibiotic by β- lactamase enzymes  Modification of target PBPs  Impaired penetration of drug to target PBPs  The presence of an efflux pump
Pharmacokinetics of Penicillins G  It is relatively unstable in acid, thus the bioavailability is low.  There is poor penetration into the cerebrospinal (CSF), unless inflammation is presetent.  Active renal tubular secretion results in a short half- life. Spectrum of activity  G+ cocci : Pneumococci , Staphylococci, Streptococci , (many Staphylococci are now resistant)  G- cocci: Meningococci and gonococci  G+ bacilli: Bacillus perfringens, Bacillus diphtheriae  Spirochetes: Treponema pallidum, Leptospira and Actinomyces
Therapeutic uses  It is the drug of first choice for treating the infections of the above mentioned pathogens.  The simultaneous administration of the relevant antitoxin is often necessary for the treatment of diphtheria and tetanus.  The combination of an aminoglycoside is also necessary for bactericidal effects in enterococcal endocarditis.
Acid-stable Penicillins- penicillin V  The oral form of penicillins,  Indicated only in minor infections because of their relatively poor bioavailability, weaker antimicrobial activity, the need for dosing many times  Narrow antimicrobial spectrum.
Penicillins: Adverse effects  Hypersensitivity –  5 to 20 % skin rashes, fever, eosinophilia, angioedema, serum sickness, and anaphylactic shock.  Cross-reactivity exists among all penicillins and even other b-lactams  The most serious hypersensitivity reaction is anaphylactic shock. (very rare, the ratio is about 0.5 to 1 of 10000 patients )  As soon as anaphylactic shock occurs, instantly inject adrenaline to deliver trachea edema and spasm.
Penicillins: Adverse effects  Other adverse effects:  Gastrointestinal upset, ( orally administered preparations)  Nephrotoxicity, is very rare.  Superinfections.  results from alterations in intestinal flora. A higher incidence occurs with broad-spectrum penicillins.
Cephalosporins  The cephalosporins are derivatives of 7- amino- cephalosporanic acid and are closely related in structure to penicillin.  They have a beta- lactamring.  They are relatively stable in dilute acid and are highly resistant to penicillinase. Mechanism of action  Cephalosporins inhibit the peptido- glycansynthesis of bacterial cell wall in a manner similar to that of penicillin and are considered bactericidal.
Classification of cephalosporins  First-generation cephalosporins  Second-generation cephalosporins  Third-generation cephalosporins  Fouth-generation cephalosporins
First Generation Cephalosporins EXAMPLES: cephalothin, cefazolin, and cephalexinet al  They have a stronger antimicrobial action on G+ bacteria than that of the other generations, but they action on G- bacteria is relatively poor.  These cephalosporinshave nephrotoxicity to a certain degree.  They are NOT effective against pseudomonas.  Comparatively, they are stable for beta- lactamase(penicillinase).  They are chiefly used in treating infection of the penicillinase-productive aurococcus (S.aureus)and surgical prophylaxisction.  Cefazolindo not penetrate the central nervous system and can not be used to treat meningitis.
Second Generation Cephalosporins Example: cefamandole, cefoxitin, cefaclor, cefonicid, cefuroxime, cefotetan, cefprozil.  Action of this generation on G+ bacteria is the same or a little bit less than that of the first generation.  Their antimicrobial action on G- bacteria is obviously increased  Some of them are effective against anaerobes such as B. fragilis.  Ineffective against P. aeruginosa.  They are stable to many kinds of beta- lactamases and have less nephrotoxicity than the first generation.  Cefuroxime is the only second-generation drug that crosses the blood-brain barrier well enough to be used for thetreatment of meningitis, especially H.influenzae meningitis, and sepsis.
Third Generation Cephalosporins Example: cefotaxime, ceftizoxime, ceftriaxone, cefoperazone, ceftazidime, cefixime, cefpodoxime  The broadest spectrums of all Cephalosporins  The highest activities against G- bacteria.  The lowest activities against G+ bacteria.  The highest resistance to β-lactamase.  The best penetration into the CSF; almost no nephrotoxicity.  Ceftizoximehave good activity against B. fragilis.  Some of them are effective against P. aeruginosa and enteric bacilli.  They are chiefly used in the infections of the urethral or biliary tract with the drug-resistant strains and Pseudomonas.  They are also used in some serious pneumonia, sepsis and meningitis.
Macrolides antibiotics Example: Erythromycin, Clarithromycin and Azithromycin M/A: Macrolide antibiotics are bacteriostatic agents that inhibit protein synthesis by binding reversibly to 50S ribosomal subunits of sensitive microorganisms. Erythromycin does not inhibit peptide bond formation per se, but rather inhibits the translocation step wherein a newly synthesized peptidyl tRNA molecule moves from the acceptor site on the ribosome to the peptidyl donor site. Gram-positive bacteria accumulate about 100 times more erythromycin than do gram-negative bacteria. Cells are considerably more permeable to the un- ionized form of the drug, which probably explains the increased antimicrobial activity at alkaline pH.
Resistance:  Resistance to macrolides can result from:  Drug efflux by an active pump mechanism;  Ribosomal protection by inducible or constitutive production of methylase enzymes that modify the ribosomal target and decrease drug binding;  macrolide hydrolysis by esterases produced by Enterobacteriaceae; and  Chromosomal mutations that alter a 50S ribosomal protein.
Absorption, Distribution, and Excretion:  Orally absorbed, erythromycin from enteric coated tablet others oral absorption is good, metabolized in the liver, excreted in the bile and some through urine.  Distributed throughout the tissues except brain & CSF. Therapeutic Uses:  Mycoplasma pneumoniae, Legionnaire disease, Chlamydia infections, Helicobacter pylori infection, Diphtheria, Streptococcal infection, Campylobacter infections, Tetanus, Syphilis, Mycobacterium infections, other infections.  Prophylactic use in recurrent rheumatic fever.  The drug cannot be used in patients sensitive to macrolide antibiotics.  Cannot be used in chronic liver diseases.
Therapeutic use of tetracyclines:  Rickettsial infections (Rocky Mountain spotted fever), Mycoplasma infections (Mycoplasma pneumoniae), Chlamydia (Pneumonia, bronchitis or sinusitis caused by Chlamydia responds to tetracycline therapy), Doxycycline is effective in reducing stool volume in Vibrio cholerae, not effective in S. Typhosa and Shigellosis due drug resistance.  Sexually transmitted diseases: Uncomplicated gonococal infections  Chlortetracycline is 30% absorbed in oral dose, but oxy and tetracycline absorbed up to 60-80%, Doxy and minocycline, 95-100% Resistance plasmid mediated, decreased influx, decreased entry to ribosome’s because of ribosome protection enzymes.
Aminoglycosides M/A: The aminoglycoside antibiotics are rapidly bactericidal. Bacterial killing is concentration-dependent: The higher the concentration, the greater is the rate at which bacteria are killed. Aminoglycosides diffuse through aqueous channels formed by porin proteins in the outer membrane of gram-negative bacteria to enter the periplasmic space. Drug is then actively transported across the cell membrane into the cytoplasm by an oxygen-dependent process. The transmembrane electrochemical gradient supplies the energy for this process, and transport is coupled to a proton pump. Low extracellular pH and anaerobic conditions inhibit transport by reducing the gradient. Transport may be enhanced by cell wall-active drugs such as penicillin or vancomycin; this enhancement may be the basis of the synergism of these antibiotics with aminoglycosides.
Therapeutic Uses: STREPTOMYCIN:  Tularemia: Streptomycin (or gentamicin) is the drug of choice for the treatment of tularemia. Most cases respond to the administration of 1 g (15 to 25 mg/kg) streptomycin per day (in divided doses) for 7 to 10 days.  Brucellosis: streptomycin, 1 g/d (15 mg/kg/d for children), is given intramuscularly in combination with an oral tetracycline.  Bacterial Endocarditis  Urinary Tract Infection  Tuberculosis
Therapeutic Uses:  GENTAMICIN:  Skin & Soft Tissue Infections  Wound, burn  Bacterial Endocarditis  Urinary Tract Infection  Tuberculosis  Tularemia  Neomycin: Ointments, often formulated as a neomycin- polymyxin-bacitracin combination, can be applied to infected skin lesions.

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Antibacterial agents

  • 1.
  • 2. Antibacterial agents Antibiotics: Antibiotics are chemical substances produced by various species of microorganisms such as bacteria, fungi, actinomycetes etc and are used for either killing or inhibiting the growth of other pathogenic microorganisms without affecting the host tissue.
  • 3. Properties of an ideal antibiotic:  It should have a broad spectrum of antimicrobial activity.  It should exert its action in low concentration  It should have bactericidal activity rather than bacteriostatic activity  It should exhibit selective and effective antimicrobial activity.  It should be highly toxic for the parasite but completely atoxic for the host.  No bacterial resistance should be developed rapidly.  It should not interfere with the host’s natural defense mechanism such as phagocytosis and production of antibodies.
  • 4.  It should have sufficient solubility in aqueous fluid to facilitate good distribution to all body tissues.  It should be excreted in urine in bactericidal concentration specially in urinary tract infection.  It’s antimicrobial efficacy should not be reduced by body fluids, exudates, plasma protein or tissue enzymes.  Antibiotic should possess sufficient chemical stability that it can be isolated, processed that stored for reasonable length of time without deterioration of potency.  The rates of biotransformation and elimination of the antibiotic should be sufficiently slow to allow a convenient dosing schedule. Properties of an ideal antibiotic: cont…
  • 5. Tetracycline Example: Oxytetracycline, Demeclocycline, Methacycline. M/A: Tetracyclines inhibit bacterial protein synthesis by binding to the 30S bacterial ribosome and preventing access of aminoacyl tRNA to the acceptor (A) site on the mRNA-ribosome complex. These drugs enter gram-negative bacteria by passive diffusion through the hydrophilic channels formed by the porin proteins of the outer cell membrane and by active transport via an energy-dependent system that pumps all tetracyclines across the cytoplasmic membrane. Entry of these drugs into gram-positive bacteria requires metabolic energy, but is not as well understood.
  • 6. Mechanism of antibacterial action There are five main mechanisms by which antibacterial agent act- Inhibition of cell metabolism: Antibacterial agents which inhibit cell metabolism are called antimetabolites. These compounds inhibit the metabolism of microorganism but not the metabolism of the host. They can do this by inhibiting an enzyme catalyzed reaction which is present in the bacterial cell, but not in animal cells. e. g. sulfonamides. Inhibition of bacterial cell wall synthesis: Inhibition of bacterial cell wall synthesis leads to bacterial cell lysis and death.
  • 7. Interaction with plasma membrane: Some antibacterial agents interact with the plasma membrane of bacterial cells to affect the membrane permeability. This has fatal results for the cell. E. g. polymixins, tyrothricin. Disruption of protein synthesis: Disruption of protein synthesis means that essential proteins and enzymes required for the cell’s survival can no longer be made. E. g. rifamycins, aminoglycosides, tetracyclins and chloramphenicol Inhibition of nucleic acid transcription and replication Inhibition of nucleic acid function prevents cell division and/or the synthesis of essential proteins. e. g. –nalidixic acid, proflavin, fluoroquinolone
  • 8. Classification of Antibiotics: Although there are several classification schemes for antibiotics, based on bacterial spectrum (broad versus narrow) or type of activity (bactericidal vs. bacteriostatic), the most useful is based on chemical structure. Antibiotics within a structural class will generally have similar patterns of effectiveness, toxicity, and allergic potential. The main classes of antibiotics are:  Beta-Lactams  Penicillins  Cephalosporins  Macrolides  Fluoroquinolones  Tetracyclines  Aminoglycosides
  • 9.
  • 10. β-Lactam Characteristics  Same Mechanism of Action : Inhibit cell wall synthesis  Bactericidal (except against Enterococcus sp.); time-dependent killers  Short elimination half-life  Primarily renal elimination  Cross-allergenicity -except aztreonam
  • 11. Mechanism of Action (ALL β-lactams)  Interfere with cell wall synthesis by binding to penicillin-binding proteins (PBPs) which are located in bacterial cell walls  Inhibition of PBPs leads to inhibition of peptidoglycan synthesis→ Cell death
  • 12. Mechanisms of Resistance 1. production of β-lactamase enzymes  most important and most common  hydrolyzes beta-lactamring causing inactivation 2. Trapping mechanism  Some β –lactams tightly bind with β – lactamase and stay outside the bacterial cell. Thus, these beta- lactams can’t enter the bacterial cell wall to combine with the PBPs. 3. Modification of target PBPs.  responsible for methicillin resistance in staphylococci and penicillin resistance in pneumococci.
  • 13. Mechanisms of Resistance 4. Impaired penetration of drug to target PBPs.  which occurs only in G-species, is due to impermeability of the outer membrane that is present in G- but not in G+ bacteria. 5. The shortage of autolytic enzyme.  Under this circumstance, the beta-lactams have normal inhibiting action, but their kill effects are very poor. 6. The presence of an efflux pump.  Some organisms also may transport beta- lactam antibiotics from the periplasm back across the cell wall via an efflux pump
  • 14. Penicillins  The structure of the penicillins consists of a thiazolidine ring connected to a beta-lactamring, which is attached to a side chain.  All penicillins are derived from 6-Amino- penicillanic acid.  The various penicillins differ in their side chain structure.
  • 15. Classification of penicillin  Penicillins are divided into natural and semisynthetic ones  Natural penicillins: extracted from the cultural solution of penicillia.  penicillin G  Is pH sensitive. Therefore not given orally.  Effective against Gram-positive cells  Susceptible to penicillinase  Semisynthetic penicillins:  Produce by growing Penicillium in culture so that only the nucleus is synthesized. Attach R group in lab.  Or, grow Penicillium, extract natural penicillin, remove R group, and attach wanted R group.  Have broader spectrum. Are effective against Gram-negative cells, too.  Are not resistant to penicillinases
  • 16. Semisynthetic penicillins:  Acid-stable penicillins(e.g. penicillin V);  Penicillinase-resistant penicillins (e.g. oxacillin);  Extended-spectrum penicillins (e.g. ampicillinand antipseudomonal);  Antistaphylococcal penicillins (e.g. nafcillin).
  • 17. Mechanisms of Resistance - Penicillins  Inactivation of antibiotic by β- lactamase enzymes  Modification of target PBPs  Impaired penetration of drug to target PBPs  The presence of an efflux pump
  • 18. Pharmacokinetics of Penicillins G  It is relatively unstable in acid, thus the bioavailability is low.  There is poor penetration into the cerebrospinal (CSF), unless inflammation is presetent.  Active renal tubular secretion results in a short half- life. Spectrum of activity  G+ cocci : Pneumococci , Staphylococci, Streptococci , (many Staphylococci are now resistant)  G- cocci: Meningococci and gonococci  G+ bacilli: Bacillus perfringens, Bacillus diphtheriae  Spirochetes: Treponema pallidum, Leptospira and Actinomyces
  • 19. Therapeutic uses  It is the drug of first choice for treating the infections of the above mentioned pathogens.  The simultaneous administration of the relevant antitoxin is often necessary for the treatment of diphtheria and tetanus.  The combination of an aminoglycoside is also necessary for bactericidal effects in enterococcal endocarditis.
  • 20. Acid-stable Penicillins- penicillin V  The oral form of penicillins,  Indicated only in minor infections because of their relatively poor bioavailability, weaker antimicrobial activity, the need for dosing many times  Narrow antimicrobial spectrum.
  • 21. Penicillins: Adverse effects  Hypersensitivity –  5 to 20 % skin rashes, fever, eosinophilia, angioedema, serum sickness, and anaphylactic shock.  Cross-reactivity exists among all penicillins and even other b-lactams  The most serious hypersensitivity reaction is anaphylactic shock. (very rare, the ratio is about 0.5 to 1 of 10000 patients )  As soon as anaphylactic shock occurs, instantly inject adrenaline to deliver trachea edema and spasm.
  • 22. Penicillins: Adverse effects  Other adverse effects:  Gastrointestinal upset, ( orally administered preparations)  Nephrotoxicity, is very rare.  Superinfections.  results from alterations in intestinal flora. A higher incidence occurs with broad-spectrum penicillins.
  • 23. Cephalosporins  The cephalosporins are derivatives of 7- amino- cephalosporanic acid and are closely related in structure to penicillin.  They have a beta- lactamring.  They are relatively stable in dilute acid and are highly resistant to penicillinase. Mechanism of action  Cephalosporins inhibit the peptido- glycansynthesis of bacterial cell wall in a manner similar to that of penicillin and are considered bactericidal.
  • 24. Classification of cephalosporins  First-generation cephalosporins  Second-generation cephalosporins  Third-generation cephalosporins  Fouth-generation cephalosporins
  • 25. First Generation Cephalosporins EXAMPLES: cephalothin, cefazolin, and cephalexinet al  They have a stronger antimicrobial action on G+ bacteria than that of the other generations, but they action on G- bacteria is relatively poor.  These cephalosporinshave nephrotoxicity to a certain degree.  They are NOT effective against pseudomonas.  Comparatively, they are stable for beta- lactamase(penicillinase).  They are chiefly used in treating infection of the penicillinase-productive aurococcus (S.aureus)and surgical prophylaxisction.  Cefazolindo not penetrate the central nervous system and can not be used to treat meningitis.
  • 26. Second Generation Cephalosporins Example: cefamandole, cefoxitin, cefaclor, cefonicid, cefuroxime, cefotetan, cefprozil.  Action of this generation on G+ bacteria is the same or a little bit less than that of the first generation.  Their antimicrobial action on G- bacteria is obviously increased  Some of them are effective against anaerobes such as B. fragilis.  Ineffective against P. aeruginosa.  They are stable to many kinds of beta- lactamases and have less nephrotoxicity than the first generation.  Cefuroxime is the only second-generation drug that crosses the blood-brain barrier well enough to be used for thetreatment of meningitis, especially H.influenzae meningitis, and sepsis.
  • 27. Third Generation Cephalosporins Example: cefotaxime, ceftizoxime, ceftriaxone, cefoperazone, ceftazidime, cefixime, cefpodoxime  The broadest spectrums of all Cephalosporins  The highest activities against G- bacteria.  The lowest activities against G+ bacteria.  The highest resistance to β-lactamase.  The best penetration into the CSF; almost no nephrotoxicity.  Ceftizoximehave good activity against B. fragilis.  Some of them are effective against P. aeruginosa and enteric bacilli.  They are chiefly used in the infections of the urethral or biliary tract with the drug-resistant strains and Pseudomonas.  They are also used in some serious pneumonia, sepsis and meningitis.
  • 28. Macrolides antibiotics Example: Erythromycin, Clarithromycin and Azithromycin M/A: Macrolide antibiotics are bacteriostatic agents that inhibit protein synthesis by binding reversibly to 50S ribosomal subunits of sensitive microorganisms. Erythromycin does not inhibit peptide bond formation per se, but rather inhibits the translocation step wherein a newly synthesized peptidyl tRNA molecule moves from the acceptor site on the ribosome to the peptidyl donor site. Gram-positive bacteria accumulate about 100 times more erythromycin than do gram-negative bacteria. Cells are considerably more permeable to the un- ionized form of the drug, which probably explains the increased antimicrobial activity at alkaline pH.
  • 29. Resistance:  Resistance to macrolides can result from:  Drug efflux by an active pump mechanism;  Ribosomal protection by inducible or constitutive production of methylase enzymes that modify the ribosomal target and decrease drug binding;  macrolide hydrolysis by esterases produced by Enterobacteriaceae; and  Chromosomal mutations that alter a 50S ribosomal protein.
  • 30. Absorption, Distribution, and Excretion:  Orally absorbed, erythromycin from enteric coated tablet others oral absorption is good, metabolized in the liver, excreted in the bile and some through urine.  Distributed throughout the tissues except brain & CSF. Therapeutic Uses:  Mycoplasma pneumoniae, Legionnaire disease, Chlamydia infections, Helicobacter pylori infection, Diphtheria, Streptococcal infection, Campylobacter infections, Tetanus, Syphilis, Mycobacterium infections, other infections.  Prophylactic use in recurrent rheumatic fever.  The drug cannot be used in patients sensitive to macrolide antibiotics.  Cannot be used in chronic liver diseases.
  • 31. Therapeutic use of tetracyclines:  Rickettsial infections (Rocky Mountain spotted fever), Mycoplasma infections (Mycoplasma pneumoniae), Chlamydia (Pneumonia, bronchitis or sinusitis caused by Chlamydia responds to tetracycline therapy), Doxycycline is effective in reducing stool volume in Vibrio cholerae, not effective in S. Typhosa and Shigellosis due drug resistance.  Sexually transmitted diseases: Uncomplicated gonococal infections  Chlortetracycline is 30% absorbed in oral dose, but oxy and tetracycline absorbed up to 60-80%, Doxy and minocycline, 95-100% Resistance plasmid mediated, decreased influx, decreased entry to ribosome’s because of ribosome protection enzymes.
  • 32. Aminoglycosides M/A: The aminoglycoside antibiotics are rapidly bactericidal. Bacterial killing is concentration-dependent: The higher the concentration, the greater is the rate at which bacteria are killed. Aminoglycosides diffuse through aqueous channels formed by porin proteins in the outer membrane of gram-negative bacteria to enter the periplasmic space. Drug is then actively transported across the cell membrane into the cytoplasm by an oxygen-dependent process. The transmembrane electrochemical gradient supplies the energy for this process, and transport is coupled to a proton pump. Low extracellular pH and anaerobic conditions inhibit transport by reducing the gradient. Transport may be enhanced by cell wall-active drugs such as penicillin or vancomycin; this enhancement may be the basis of the synergism of these antibiotics with aminoglycosides.
  • 33. Therapeutic Uses: STREPTOMYCIN:  Tularemia: Streptomycin (or gentamicin) is the drug of choice for the treatment of tularemia. Most cases respond to the administration of 1 g (15 to 25 mg/kg) streptomycin per day (in divided doses) for 7 to 10 days.  Brucellosis: streptomycin, 1 g/d (15 mg/kg/d for children), is given intramuscularly in combination with an oral tetracycline.  Bacterial Endocarditis  Urinary Tract Infection  Tuberculosis
  • 34. Therapeutic Uses:  GENTAMICIN:  Skin & Soft Tissue Infections  Wound, burn  Bacterial Endocarditis  Urinary Tract Infection  Tuberculosis  Tularemia  Neomycin: Ointments, often formulated as a neomycin- polymyxin-bacitracin combination, can be applied to infected skin lesions.